Effect of polar distortions on the anomalous Hall conductivity of altermagnetic α-MnTe

Abstract

Altermagnetic α-MnTe with Néel vector along the y-axis exhibits a finite anomalous Hall conductivity (AHC) and weak ferromagnetism along the z-axis. As already demonstrated in the bulk, there is the breaking of the C6 symmetry by the in-plane Néel vector, leaving a C2-type magnetic symmetry. The surface of α-MnTe breaks the C2, leaving only a time-reversed mirror symmetry with respect to the x=0 plane. Therefore, we demonstrate that on the surface, the interplay between breaking of the crystal symmetry and Néel vector orientation produces a reduction of the space group from hexagonal P63/mmc to orthorhombic Amm2. As a result, the surface exhibits not only a polar distortion along the z-axis, but also a polar distortion and a weak ferrimagnetism along the y-axis. To describe the surface of MnTe in an accessible way, we simplify the problem and examine the effect of the in-plane electric field in bulk MnTe. Moreover, as a doped ionic semiconductor, the properties of MnTe can be influenced by lattice polarization under an applied electric field. We investigate the interplay between the intrinsic anomalous Hall effect and lattice polarization, showing that polarization effects can substantially affect the AHC. Since the electric field breaks inversion symmetry, this contribution from the lattice polarization coexists with the non-linear anomalous Hall effect, highlighting the rich transport phenomenology of altermagnets.